Provided by: python3-flask-socketio_5.3.2-1_all bug

NAME

       flask-socketio - flask-socketio Documentation

       Flask-SocketIO   gives   Flask   applications   access   to   low  latency  bi-directional
       communications between the clients and the server. The client-side application can use any
       of  the SocketIO client libraries in Javascript, Python, C++, Java and Swift, or any other
       compatible client to establish a permanent connection to the server.

INTRODUCTION

   Installation
       You can install this package in the usual way using pip:

          pip install flask-socketio

   Requirements
       Flask-SocketIO is compatible with Python 3.6+. The asynchronous services that this package
       relies on can be selected among three choices:

       • eventlet  is  the  best  performant  option, with support for long-polling and WebSocket
         transports.

       • gevent is supported in a number of different configurations. The long-polling  transport
         is  fully  supported  with the gevent package, but unlike eventlet, gevent does not have
         native WebSocket support. To add support for WebSocket there are currently two  options.
         Installing  the gevent-websocket package adds WebSocket support to gevent or one can use
         the uWSGI web server, which comes with WebSocket functionality. The  use  of  gevent  is
         also a performant option, but slightly lower than eventlet.

       • The Flask development server based on Werkzeug can be used as well, with the caveat that
         this web server is intended only for development use, so  it  should  only  be  used  to
         simplify the development workflow and not for production.

       The  extension  automatically detects which asynchronous framework to use based on what is
       installed. Preference is given to eventlet, followed by gevent.  For WebSocket support  in
       gevent,  uWSGI  is preferred, followed by gevent-websocket. If neither eventlet nor gevent
       are installed, then the Flask development server is used.

       If using multiple processes, a message queue service  must  be  configured  to  allow  the
       servers  to  coordinate  operations  such as broadcasting. The supported queues are Redis,
       RabbitMQ, Kafka, and any other message queues supported by the Kombu package.

       On the client-side, the official Socket.IO  Javascript  client  library  can  be  used  to
       establish  a  connection  to the server. There are also official clients written in Swift,
       Java and C++. Unofficial clients may also work, as long as they  implement  the  Socket.IO
       protocol.  The python-socketio package (which provides the Socket.IO server implementation
       used by Flask-SocketIO) includes a Python client.

   Version compatibility
       The Socket.IO protocol has  been  through  a  number  of  revisions,  and  some  of  these
       introduced  backward incompatible changes, which means that the client and the server must
       use compatible versions for everything to work.

       The version compatibility chart below maps versions of this package  to  versions  of  the
       JavaScript  reference  implementation  and  the  versions  of  the Socket.IO and Engine.IO
       protocols.

       ┌────────────┬───────────┬───────────┬────────────────┬─────────────────┬─────────────────┐
       │JavaScript  │ Socket.IO │ Engine.IO │ Flask-SocketIO │ python-socketio │ python-engineio │
       │Socket.IO   │ protocol  │ protocol  │ version        │ version         │ version         │
       │version     │ revision  │ revision  │                │                 │                 │
       └────────────┴───────────┴───────────┴────────────────┴─────────────────┴─────────────────┘

       │0.9.x       │ 1, 2      │ 1, 2      │ Not supported  │ Not supported   │ Not supported   │
       ├────────────┼───────────┼───────────┼────────────────┼─────────────────┼─────────────────┤
       │1.x and 2.x │ 3, 4      │ 3         │ 4.x            │ 4.x             │ 3.x             │
       ├────────────┼───────────┼───────────┼────────────────┼─────────────────┼─────────────────┤
       │3.x and 4.x │ 5         │ 4         │ 5.x            │ 5.x             │ 4.x             │
       └────────────┴───────────┴───────────┴────────────────┴─────────────────┴─────────────────┘

GETTING STARTED

   Initialization
       The following code example shows how to add Flask-SocketIO to a Flask application:

          from flask import Flask, render_template
          from flask_socketio import SocketIO

          app = Flask(__name__)
          app.config['SECRET_KEY'] = 'secret!'
          socketio = SocketIO(app)

          if __name__ == '__main__':
              socketio.run(app)

       The  init_app()  style of initialization is also supported. To start the web server simply
       execute your script. Note the way the web server is started.  The socketio.run()  function
       encapsulates  the  start  up  of  the web server and replaces the app.run() standard Flask
       development server  start  up.  When  the  application  is  in  debug  mode  the  Werkzeug
       development  server  is  still  used  and  configured  properly  inside socketio.run(). In
       production mode the eventlet web server is used if available, else the gevent  web  server
       is  used. If eventlet and gevent are not installed, the Werkzeug development web server is
       used.

       The flask run command introduced in Flask 0.11 can  be  used  to  start  a  Flask-SocketIO
       development  server  based  on  Werkzeug,  but  this method of starting the Flask-SocketIO
       server is not recommended due to lack of WebSocket support.   Previous  versions  of  this
       package  included  a  customized  version of the flask run command that allowed the use of
       WebSocket on eventlet and gevent production  servers,  but  this  functionality  has  been
       discontinued  in  favor  of the socketio.run(app) startup method shown above which is more
       robust.

       The application must serve a page to the client  that  loads  the  Socket.IO  library  and
       establishes a connection:

          <script src="https://cdnjs.cloudflare.com/ajax/libs/socket.io/4.0.1/socket.io.js" integrity="sha512-q/dWJ3kcmjBLU4Qc47E4A9kTB4m3wuTY7vkFJDTZKjTs8jhyGQnaUrxa0Ytd0ssMZhbNua9hE+E7Qv1j+DyZwA==" crossorigin="anonymous"></script>
          <script type="text/javascript" charset="utf-8">
              var socket = io();
              socket.on('connect', function() {
                  socket.emit('my event', {data: 'I\'m connected!'});
              });
          </script>

   Receiving Messages
       When  using  SocketIO, messages are received by both parties as events. On the client side
       Javascript callbacks are used. With Flask-SocketIO the server needs to  register  handlers
       for these events, similarly to how routes are handled by view functions.

       The following example creates a server-side event handler for an unnamed event:

          @socketio.on('message')
          def handle_message(data):
              print('received message: ' + data)

       The above example uses string messages. Another type of unnamed events use JSON data:

          @socketio.on('json')
          def handle_json(json):
              print('received json: ' + str(json))

       The most flexible type of event uses custom event names. The message data for these events
       can be string, bytes, int, or JSON:

          @socketio.on('my event')
          def handle_my_custom_event(json):
              print('received json: ' + str(json))

       Custom named events can also support multiple arguments:

          @socketio.on('my_event')
          def handle_my_custom_event(arg1, arg2, arg3):
              print('received args: ' + arg1 + arg2 + arg3)

       When the name of the event is a valid Python identifier that does not collide  with  other
       defined  symbols,  the @socketio.event decorator provides a more compact syntax that takes
       the event name from the decorated function:

          @socketio.event
          def my_custom_event(arg1, arg2, arg3):
              print('received args: ' + arg1 + arg2 + arg3)

       Named events are the most flexible, as they  eliminate  the  need  to  include  additional
       metadata to describe the message type. The names message, json, connect and disconnect are
       reserved and cannot be used for named events.

       Flask-SocketIO also supports SocketIO namespaces, which  allow  the  client  to  multiplex
       several independent connections on the same physical socket:

          @socketio.on('my event', namespace='/test')
          def handle_my_custom_namespace_event(json):
              print('received json: ' + str(json))

       When a namespace is not specified a default global namespace with the name '/' is used.

       For cases when a decorator syntax isn't convenient, the on_event method can be used:

          def my_function_handler(data):
              pass

          socketio.on_event('my event', my_function_handler, namespace='/test')

       Clients  may  request  an acknowledgement callback that confirms receipt of a message they
       sent. Any values returned from the handler function  will  be  passed  to  the  client  as
       arguments in the callback function:

          @socketio.on('my event')
          def handle_my_custom_event(json):
              print('received json: ' + str(json))
              return 'one', 2

       In  the  above  example,  the client callback function will be invoked with two arguments,
       'one' and 2. If a handler function  does  not  return  any  values,  the  client  callback
       function will be invoked without arguments.

   Sending Messages
       SocketIO  event  handlers defined as shown in the previous section can send reply messages
       to the connected client using the send() and emit() functions.

       The following examples bounce received events back to the client that sent them:

          from flask_socketio import send, emit

          @socketio.on('message')
          def handle_message(message):
              send(message)

          @socketio.on('json')
          def handle_json(json):
              send(json, json=True)

          @socketio.on('my event')
          def handle_my_custom_event(json):
              emit('my response', json)

       Note how send() and emit() are used for unnamed and named events respectively.

       When working with namespaces, send() and emit() use the namespace of the incoming  message
       by default. A different namespace can be specified with the optional namespace argument:

          @socketio.on('message')
          def handle_message(message):
              send(message, namespace='/chat')

          @socketio.on('my event')
          def handle_my_custom_event(json):
              emit('my response', json, namespace='/chat')

       To send an event with multiple arguments, send a tuple:

          @socketio.on('my event')
          def handle_my_custom_event(json):
              emit('my response', ('foo', 'bar', json), namespace='/chat')

       SocketIO supports acknowledgment callbacks that confirm that a message was received by the
       client:

          def ack():
              print('message was received!')

          @socketio.on('my event')
          def handle_my_custom_event(json):
              emit('my response', json, callback=ack)

       When using callbacks, the Javascript client receives a callback function  to  invoke  upon
       receipt  of  the  message.  After the client application invokes the callback function the
       server invokes the corresponding server-side callback.  If  the  client-side  callback  is
       invoked  with  arguments,  these  are provided as arguments to the server-side callback as
       well.

   Broadcasting
       Another very useful feature of SocketIO is the broadcasting of  messages.   Flask-SocketIO
       supports this feature with the broadcast=True optional argument to send() and emit():

          @socketio.on('my event')
          def handle_my_custom_event(data):
              emit('my response', data, broadcast=True)

       When  a  message  is  sent with the broadcast option enabled, all clients connected to the
       namespace receive it, including the sender. When namespaces  are  not  used,  the  clients
       connected to the global namespace receive the message. Note that callbacks are not invoked
       for broadcast messages.

       In all the examples shown until this point the server responds to an  event  sent  by  the
       client.  But  for  some  applications, the server needs to be the originator of a message.
       This can be useful to send notifications to clients  of  events  that  originated  in  the
       server,  for  example  in  a  background  thread.  The socketio.send() and socketio.emit()
       methods can be used to broadcast to all connected clients:

          def some_function():
              socketio.emit('some event', {'data': 42})

       Note  that  socketio.send()  and  socketio.emit()  are  not  the  same  functions  as  the
       context-aware  send()  and  emit().  Also  note that in the above usage there is no client
       context, so broadcast=True is assumed and does not need to be specified.

   Rooms
       For many applications it is necessary to group users into subsets that  can  be  addressed
       together.  The best example is a chat application with multiple rooms, where users receive
       messages from the room or rooms they are in, but not from other rooms  where  other  users
       are.   Flask-SocketIO   supports  this  concept  of  rooms  through  the  join_room()  and
       leave_room() functions:

          from flask_socketio import join_room, leave_room

          @socketio.on('join')
          def on_join(data):
              username = data['username']
              room = data['room']
              join_room(room)
              send(username + ' has entered the room.', to=room)

          @socketio.on('leave')
          def on_leave(data):
              username = data['username']
              room = data['room']
              leave_room(room)
              send(username + ' has left the room.', to=room)

       The send() and emit() functions accept an optional to argument that cause the  message  to
       be sent to all the clients that are in the given room.

       All  clients  are  assigned  a  room  when  they connect, named with the session ID of the
       connection, which can be obtained from request.sid. A given client  can  join  any  rooms,
       which  can  be given any names. When a client disconnects it is removed from all the rooms
       it was in. The context-free socketio.send() and socketio.emit() functions also accept a to
       argument to broadcast to all clients in a room.

       Since  all  clients are assigned a personal room, to address a message to a single client,
       the session ID of the client can be used as the to argument.

   Connection Events
       Flask-SocketIO also dispatches connection and disconnection events. The following  example
       shows how to register handlers for them:

          @socketio.on('connect')
          def test_connect(auth):
              emit('my response', {'data': 'Connected'})

          @socketio.on('disconnect')
          def test_disconnect():
              print('Client disconnected')

       The  auth  argument  in  the connection handler is optional. The client can use it to pass
       authentication data such as tokens in dictionary format. If the client  does  not  provide
       authentication  details,  then  this  argument  is  set  to  None. If the server defines a
       connection event handler without this argument, then any authentication data passed by the
       client is discarded.

       The  connection  event  handler  can return False to reject the connection, or it can also
       raise ConnectionRefusedError. This is so that the client  can  be  authenticated  at  this
       point. When using the exception, any arguments passed to the exception are returned to the
       client in the error packet. Examples:

          from flask_socketio import ConnectionRefusedError

          @socketio.on('connect')
          def connect():
              if not self.authenticate(request.args):
                  raise ConnectionRefusedError('unauthorized!')

       Note that connection and disconnection events are  sent  individually  on  each  namespace
       used.

   Class-Based Namespaces
       As  an  alternative  to  the  decorator-based  event  handlers  described above, the event
       handlers that  belong  to  a  namespace  can  be  created  as  methods  of  a  class.  The
       flask_socketio.Namespace is provided as a base class to create class-based namespaces:

          from flask_socketio import Namespace, emit

          class MyCustomNamespace(Namespace):
              def on_connect(self):
                  pass

              def on_disconnect(self):
                  pass

              def on_my_event(self, data):
                  emit('my_response', data)

          socketio.on_namespace(MyCustomNamespace('/test'))

       When  class-based namespaces are used, any events received by the server are dispatched to
       a method named as the event name with the on_ prefix. For example, event my_event will  be
       handled  by  a  method  named  on_my_event.  If an event is received for which there is no
       corresponding method defined in the namespace class, then the event is ignored. All  event
       names used in class-based namespaces must use characters that are legal in method names.

       As  a  convenience  to  methods defined in a class-based namespace, the namespace instance
       includes versions of several of the methods  in  the  flask_socketio.SocketIO  class  that
       default to the proper namespace when the namespace argument is not given.

       If  an event has a handler in a class-based namespace, and also a decorator-based function
       handler, only the decorated function handler is invoked.

   Error Handling
       Flask-SocketIO can also deal with exceptions:

          @socketio.on_error()        # Handles the default namespace
          def error_handler(e):
              pass

          @socketio.on_error('/chat') # handles the '/chat' namespace
          def error_handler_chat(e):
              pass

          @socketio.on_error_default  # handles all namespaces without an explicit error handler
          def default_error_handler(e):
              pass

       Error handler functions take the exception object as an argument.

       The message and data arguments of the current request  can  also  be  inspected  with  the
       request.event  variable, which is useful for error logging and debugging outside the event
       handler:

          from flask import request

          @socketio.on("my error event")
          def on_my_event(data):
              raise RuntimeError()

          @socketio.on_error_default
          def default_error_handler(e):
              print(request.event["message"]) # "my error event"
              print(request.event["args"])    # (data,)

   Debugging and Troubleshooting
       To help you debug issues, the server can be configured to output logs to the terminal:

          socketio = SocketIO(logger=True, engineio_logger=True)

       The  logger  argument  controls  logging  related  to  the   Socket.IO   protocol,   while
       engineio_logger  controls  logs that originate in the low-level Engine.IO transport. These
       arguments can be set to True to output logs to stderr, or to  an  object  compatible  with
       Python's  logging  package  where the logs should be emitted to. A value of False disables
       logging.

       Logging can help identify the cause of connection problems, 400 responses, bad performance
       and other issues.

IMPLEMENTATION NOTES

   Access to Flask's Context Globals
       Handlers  for SocketIO events are different than handlers for routes and that introduces a
       lot of confusion around what can and cannot be  done  in  a  SocketIO  handler.  The  main
       difference  is that all the SocketIO events generated for a client occur in the context of
       a single long running request.

       In spite of the differences, Flask-SocketIO attempts to make working with  SocketIO  event
       handlers  easier  by making the environment similar to that of a regular HTTP request. The
       following list describes what works and what doesn't:

       • An application context is pushed before invoking an event handler making current_app and
         g available to the handler.

       • A  request  context  is  also  pushed before invoking a handler, also making request and
         session available. But note that  WebSocket  events  do  not  have  individual  requests
         associated  with  them, so the request context that started the connection is pushed for
         all the events that are dispatched during the life of the connection.

       • The request context global is enhanced with a sid member that is set to a unique session
         ID for the connection. This value is used as an initial room where the client is added.

       • The request context global is enhanced with namespace and event members that contain the
         currently handled namespace and event arguments.  The event member is a dictionary  with
         message and args keys.

       • The  session  context global behaves in a different way than in regular requests. A copy
         of the user session at the time the SocketIO connection is established is made available
         to  handlers  invoked  in the context of that connection. If a SocketIO handler modifies
         the session, the modified session will be preserved for future  SocketIO  handlers,  but
         regular  HTTP  route  handlers  will not see these changes. Effectively, when a SocketIO
         handler modifies the session, a "fork" of the session is created exclusively  for  these
         handlers.  The  technical  reason for this limitation is that to save the user session a
         cookie needs to be sent to the client, and that  requires  HTTP  request  and  response,
         which  do  not  exist  in a SocketIO connection. When using server-side sessions such as
         those provided by the Flask-Session or Flask-KVSession extensions, changes made  to  the
         session  in HTTP route handlers can be seen by SocketIO handlers, as long as the session
         is not modified in the SocketIO handlers.

       • The before_request and after_request hooks are not invoked for SocketIO event handlers.

       • SocketIO handlers can take custom decorators, but most  Flask  decorators  will  not  be
         appropriate  to use for a SocketIO handler, given that there is no concept of a Response
         object during a SocketIO connection.

   Authentication
       A common need of applications is to validate the identity of their users. The  traditional
       mechanisms  based  on web forms and HTTP requests cannot be used in a SocketIO connection,
       since there is no place to send HTTP requests and responses. If necessary, an  application
       can  implement  a customized login form that sends credentials to the server as a SocketIO
       message when the submit button is pressed by the user.

       However, in most cases it is more convenient to  perform  the  traditional  authentication
       process  before  the  SocketIO  connection is established. The user's identity can then be
       recorded in the user session or in a cookie, and later when  the  SocketIO  connection  is
       established that information will be accessible to SocketIO event handlers.

       Recent  revisions  of the Socket.IO protocol include the ability to pass a dictionary with
       authentication information during the connection. This is an ideal place for the client to
       include  a token or other authentication details.  If the client uses this capability, the
       server will provide this dictionary as an argument to the connect event handler, as  shown
       above.

   Using Flask-Login with Flask-SocketIO
       Flask-SocketIO  can  access  login  information maintained by Flask-Login. After a regular
       Flask-Login authentication is performed and the login_user() function is called to  record
       the  user  in  the  user  session,  any  SocketIO  connections  will  have  access  to the
       current_user context variable:

          @socketio.on('connect')
          def connect_handler():
              if current_user.is_authenticated:
                  emit('my response',
                       {'message': '{0} has joined'.format(current_user.name)},
                       broadcast=True)
              else:
                  return False  # not allowed here

       Note that the login_required decorator cannot be used with SocketIO event handlers, but  a
       custom decorator that disconnects non-authenticated users can be created as follows:

          import functools
          from flask import request
          from flask_login import current_user
          from flask_socketio import disconnect, emit

          def authenticated_only(f):
              @functools.wraps(f)
              def wrapped(*args, **kwargs):
                  if not current_user.is_authenticated:
                      disconnect()
                  else:
                      return f(*args, **kwargs)
              return wrapped

          @socketio.on('my event')
          @authenticated_only
          def handle_my_custom_event(data):
              emit('my response', {'message': '{0} has joined'.format(current_user.name)},
                   broadcast=True)

DEPLOYMENT

       There  are  many  options  to  deploy  a Flask-SocketIO server, ranging from simple to the
       insanely complex. In this section, the most commonly used options are described.

   Embedded Server
       The simplest deployment strategy is to start the web server by  calling  socketio.run(app)
       as shown in examples above. This will look through the packages that are installed for the
       best available web server start the application on it. The current web server choices that
       are evaluated are eventlet, gevent and the Flask development server.

       If  eventlet  or  gevent are available, socketio.run(app) starts a production-ready server
       using one of these  frameworks.  If  neither  of  these  are  installed,  then  the  Flask
       development  web server is used, and in this case the server is not intended to be used in
       a production deployment.

       Unfortunately this option is not available when using gevent with  uWSGI.  See  the  uWSGI
       section below for information on this option.

   Gunicorn Web Server
       An  alternative  to socketio.run(app) is to use gunicorn as web server, using the eventlet
       or gevent workers. For this option, eventlet or gevent need to be installed,  in  addition
       to gunicorn. The command line that starts the eventlet server via gunicorn is:

          gunicorn --worker-class eventlet -w 1 module:app

       If you prefer to use gevent, the command to start the server is:

          gunicorn -k gevent -w 1 module:app

       When  using  gunicorn  with  the  gevent  worker  and  the  WebSocket  support provided by
       gevent-websocket, the command that starts the server must be changed to  select  a  custom
       gevent web server that supports the WebSocket protocol. The modified command is:

          gunicorn -k geventwebsocket.gunicorn.workers.GeventWebSocketWorker -w 1 module:app

       A   third   option   with  Gunicorn  is  to  use  the  threaded  worker,  along  with  the
       simple-websocket package for WebSocket support. This is a particularly good  solution  for
       applications that are CPU heavy or are otherwise incompatible with eventlet and gevent use
       of green threads. The command to start a threaded web server is:

          gunicorn -w 1 --threads 100 module:app

       In all these commands, module is the Python module or package that defines the application
       instance, and app is the application instance itself.

       Due  to  the  limited load balancing algorithm used by gunicorn, it is not possible to use
       more than one worker process when using this web server. For that reason, all the examples
       above include the -w 1 option.

       The  workaround  to  use  multiple  worker  processes  with  gunicorn is to launch several
       single-worker instances and put them behind a more capable load balancer such as nginx.

   uWSGI Web Server
       When using the uWSGI server in combination with gevent,  the  Socket.IO  server  can  take
       advantage of uWSGI’s native WebSocket support.

       A  complete  explanation  of the configuration and usage of the uWSGI server is beyond the
       scope of this documentation. The uWSGI server is a fairly complex package that provides  a
       large and comprehensive set of options. It must be compiled with WebSocket and SSL support
       for the WebSocket transport to be available. As way  of  an  introduction,  the  following
       command starts a uWSGI server for the example application app.py on port 5000:

          $ uwsgi --http :5000 --gevent 1000 --http-websockets --master --wsgi-file app.py --callable app

   Using nginx as a WebSocket Reverse Proxy
       It  is  possible  to  use  nginx  as a front-end reverse proxy that passes requests to the
       application. However, only releases of  nginx  1.4  and  newer  support  proxying  of  the
       WebSocket  protocol.  Below is a basic nginx configuration that proxies HTTP and WebSocket
       requests:

          server {
              listen 80;
              server_name _;

              location / {
                  include proxy_params;
                  proxy_pass http://127.0.0.1:5000;
              }

              location /static {
                  alias <path-to-your-application>/static;
                  expires 30d;
              }

              location /socket.io {
                  include proxy_params;
                  proxy_http_version 1.1;
                  proxy_buffering off;
                  proxy_set_header Upgrade $http_upgrade;
                  proxy_set_header Connection "Upgrade";
                  proxy_pass http://127.0.0.1:5000/socket.io;
              }
          }

       The next example adds the support for load balancing multiple Socket.IO servers:

          upstream socketio_nodes {
              ip_hash;

              server 127.0.0.1:5000;
              server 127.0.0.1:5001;
              server 127.0.0.1:5002;
              # to scale the app, just add more nodes here!
          }

          server {
              listen 80;
              server_name _;

              location / {
                  include proxy_params;
                  proxy_pass http://127.0.0.1:5000;
              }

              location /static {
                  alias <path-to-your-application>/static;
                  expires 30d;
              }

              location /socket.io {
                  include proxy_params;
                  proxy_http_version 1.1;
                  proxy_buffering off;
                  proxy_set_header Upgrade $http_upgrade;
                  proxy_set_header Connection "Upgrade";
                  proxy_pass http://socketio_nodes/socket.io;
              }
          }

       While the above examples can work as an initial configuration, be aware that a  production
       install of nginx will need a more complete configuration covering other deployment aspects
       such as SSL support.

   Using Multiple Workers
       Flask-SocketIO supports multiple workers behind a load balancer starting with release 2.0.
       Deploying  multiple  workers  gives  applications  that  use Flask-SocketIO the ability to
       spread the client connections among multiple processes and hosts, and in this way scale to
       support very large numbers of concurrent clients.

       There are two requirements to use multiple Flask-SocketIO workers:

       • The  load  balancer  must be configured to forward all HTTP requests from a given client
         always to the same worker. This is sometimes referenced as "sticky sessions". For nginx,
         use  the  ip_hash  directive  to  achieve  this.   Gunicorn cannot be used with multiple
         workers because its load balancer algorithm does not support sticky sessions.

       • Since each of the servers owns only a subset of the client connections, a message  queue
         such  as  Redis or RabbitMQ is used by the servers to coordinate complex operations such
         as broadcasting and rooms.

       When working with a message queue, there are  additional  dependencies  that  need  to  be
       installed:

       • For Redis, the package redis must be installed (pip install redis).

       • For RabbitMQ, the package kombu must be installed (pip install kombu).

       • For Kafka, the package kafka-python must be installed (pip install kafka-python).

       • For  other  message  queues  supported by Kombu, see the Kombu documentation to find out
         what dependencies are needed.

       • If eventlet or gevent are used, then monkey patching  the  Python  standard  library  is
         normally required to force the message queue package to use coroutine friendly functions
         and classes.

       For eventlet, monkey patching is done with:

          import eventlet
          eventlet.monkey_patch()

       For gevent, you can monkey patch the standard library with:

          from gevent import monkey
          monkey.patch_all()

       In both cases it is recommended that you apply the monkey patching at the top of your main
       script, even above your imports.

       To start multiple Flask-SocketIO servers, you must first ensure you have the message queue
       service running. To start a Socket.IO server and have it connect to the message queue, add
       the message_queue argument to the SocketIO constructor:

          socketio = SocketIO(app, message_queue='redis://')

       The value of the message_queue argument is the connection URL of the queue service that is
       used. For a redis queue running on the same host as the server, the 'redis://' URL can  be
       used. Likewise, for a default RabbitMQ queue the 'amqp://' URL can be used. For Kafka, use
       a kafka:// URL.  The Kombu package has a documentation section that describes  the  format
       of the URLs for all the supported queues.

   Emitting from an External Process
       For  many types of applications, it is necessary to emit events from a process that is not
       the SocketIO server, for an example a Celery worker. If the SocketIO server or servers are
       configured  to  listen on a message queue as shown in the previous section, then any other
       process can create its own SocketIO instance and use it to emit events in the same way the
       server does.

       For  example,  for  an  application  that  runs on an eventlet web server and uses a Redis
       message queue, the following Python script broadcasts an event to all clients:

          socketio = SocketIO(message_queue='redis://')
          socketio.emit('my event', {'data': 'foo'}, namespace='/test')

       When using the SocketIO instance in this way, the Flask application instance is not passed
       to the constructor.

       The channel argument to SocketIO can be used to select a specific channel of communication
       through the message queue. Using a  custom  channel  name  is  necessary  when  there  are
       multiple independent SocketIO services sharing the same queue.

       Flask-SocketIO  does  not apply monkey patching when eventlet or gevent are used. But when
       working with a message queue, it is very likely that the Python package that talks to  the
       message queue service will hang if the Python standard library is not monkey patched.

       It  is  important  to  note  that  an external process that wants to connect to a SocketIO
       server does not need to use eventlet or gevent like the main server. Having a server use a
       coroutine  framework,  while  an  external  process  is not a problem. For example, Celery
       workers do not need to be configured to use eventlet  or  gevent  just  because  the  main
       server  does.  But  if  your  external process does use a coroutine framework for whatever
       reason, then monkey patching is likely  required,  so  that  the  message  queue  accesses
       coroutine friendly functions and classes.

   Cross-Origin Controls
       For  security  reasons, this server enforces a same-origin policy by default. In practical
       terms, this means the following:

       • If an incoming HTTP or WebSocket request includes the Origin header,  this  header  must
         match  the  scheme  and  host of the connection URL. In case of a mismatch, a 400 status
         code response is returned and the connection is rejected.

       • No restrictions are imposed on incoming requests that do not include the Origin header.

       If necessary, the cors_allowed_origins option can be used to  allow  other  origins.  This
       argument  can  be  set  to  a string to set a single allowed origin, or to a list to allow
       multiple origins. A special value of '*' can be used to instruct the server to  allow  all
       origins,  but  this  should be done with care, as this could make the server vulnerable to
       Cross-Site Request Forgery (CSRF) attacks.

UPGRADING TO FLASK-SOCKETIO 5.X FROM THE 4.X RELEASES

       The Socket.IO protocol recently introduced a series of backwards incompatible changes. The
       5.x  releases  of Flask-SocketIO adopted these changes, and for that reason it can only be
       used with clients that have also been updated to the current version of the  protocol.  In
       particular,  this  means that the JavaScript client must be upgraded to a 3.x release, and
       if your client hasn't been upgraded to the latest version of the Socket.IO protocol,  then
       you must use a Flask-SocketIO 4.x release.

       The   following   protocol  changes  are  of  importance,  as  they  may  affect  existing
       applications:

       • The default namespace '/' is not automatically connected anymore, and is now treated  in
         the same way as other namespaces.

       • Each namespace connection has its own sid value, different from the others and different
         from the Engine.IO sid.

       • Flask-SocketIO now uses the same ping interval and  timeout  values  as  the  JavaScript
         reference implementation, which are 25 and 5 seconds respectively.

       • The  ping/pong  mechanism has been reversed. In the current version of the protocol, the
         server issues a ping and the client responds with a pong.

       • The default allowed payload size for long--polling packets has been lowered  from  100MB
         to 1MB.

       • The io cookie is not sent to the client anymore by default.

API REFERENCE

IndexModule IndexSearch Page

AUTHOR

       Miguel Grinberg

COPYRIGHT

       2018, Miguel Grinberg

                                           Jan 16, 2023                         FLASK-SOCKETIO(1)