| PYTHON-ENGINEIO(1) | python-engineio | PYTHON-ENGINEIO(1) |
python-engineio - python-engineio Documentation
This project implements Python based Engine.IO client and server that can run standalone or integrated with a variety of Python web frameworks and applications.
Engine.IO is a lightweight transport protocol that enables real-time bidirectional event-based communication between clients (typically, though not always, web browsers) and a server. The official implementations of the client and server components are written in JavaScript. This package provides Python implementations of both, each with standard and asyncio variants.
The Engine.IO protocol is extremely simple. Once a connection between a client and a server is established, either side can send "messages" to the other side. Event handlers provided by the applications on both ends are invoked when a message is received, or when a connection is established or dropped.
The example that follows shows a simple Python client:
import engineio
eio = engineio.Client()
@eio.on('connect')
def on_connect():
print('connection established')
@eio.on('message')
def on_message(data):
print('message received with ', data)
eio.send({'response': 'my response'})
@eio.on('disconnect')
def on_disconnect():
print('disconnected from server')
eio.connect('http://localhost:5000')
eio.wait()
And here is a similar client written using the official Engine.IO Javascript client:
<script src="/path/to/engine.io.js"></script> <script>
var socket = eio('http://localhost:5000');
socket.on('open', function() { console.log('connection established'); });
socket.on('message', function(data) {
console.log('message received with ' + data);
socket.send({response: 'my response'});
});
socket.on('close', function() { console.log('disconnected from server'); }); </script>
The following application is a basic example that uses the Eventlet asynchronous server:
import engineio
import eventlet
eio = engineio.Server()
app = engineio.WSGIApp(eio, static_files={
'/': {'content_type': 'text/html', 'filename': 'index.html'}
})
@eio.on('connect')
def connect(sid, environ):
print("connect ", sid)
@eio.on('message')
def message(sid, data):
print("message ", data)
eio.send(sid, 'reply')
@eio.on('disconnect')
def disconnect(sid):
print('disconnect ', sid)
if __name__ == '__main__':
eventlet.wsgi.server(eventlet.listen(('', 5000)), app)
Below is a similar application, coded for asyncio (Python 3.5+ only) and the Uvicorn web server:
import engineio
import uvicorn
eio = engineio.AsyncServer()
app = engineio.ASGIApp(eio, static_files={
'/': {'content_type': 'text/html', 'filename': 'index.html'}
})
@eio.on('connect')
def connect(sid, environ):
print("connect ", sid)
@eio.on('message')
async def message(sid, data):
print("message ", data)
await eio.send(sid, 'reply')
@eio.on('disconnect')
def disconnect(sid):
print('disconnect ', sid)
if __name__ == '__main__':
uvicorn.run('127.0.0.1', 5000)
This package contains two Engine.IO clients:
The methods in the two clients are the same, with the only difference that in the asyncio client most methods are implemented as coroutines.
To install the standard Python client along with its dependencies, use the following command:
pip install "python-engineio[client]"
If instead you plan on using the asyncio client, then use this:
pip install "python-engineio[asyncio_client]"
To instantiate an Engine.IO client, simply create an instance of the appropriate client class:
import engineio # standard Python eio = engineio.Client() # asyncio eio = engineio.AsyncClient()
To responds to events triggered by the connection or the server, event Handler functions must be defined using the on decorator:
@eio.on('connect')
def on_connect():
print('I'm connected!')
@eio.on('message')
def on_message(data):
print('I received a message!')
@eio.on('disconnect')
def on_disconnect():
print('I'm disconnected!')
For the asyncio server, event handlers can be regular functions as above, or can also be coroutines:
@eio.on('message')
async def on_message(data):
print('I received a message!')
The argument given to the on decorator is the event name. The events that are supported are connect, message and disconnect. Note that the disconnect handler is invoked for application initiated disconnects, server initiated disconnects, or accidental disconnects, for example due to networking failures.
The data argument passed to the 'message' event handler contains application-specific data provided by the server with the event.
The connection to a server is established by calling the connect() method:
eio.connect('http://localhost:5000')
In the case of the asyncio client, the method is a coroutine:
await eio.connect('http://localhost:5000')
Upon connection, the server assigns the client a unique session identifier. The applicaction can find this identifier in the sid attribute:
print('my sid is', eio.sid)
The client can send a message to the server using the send() method:
eio.send({'foo': 'bar'})
Or in the case of asyncio, as a coroutine:
await eio.send({'foo': 'bar'})
The single argument provided to the method is the data that is passed on to the server. The data can be of type str, bytes, dict or list. The data included inside dictionaries and lists is also constrained to these types.
The send() method can be invoked inside an event handler as a response to a server event, or in any other part of the application, including in background tasks.
At any time the client can request to be disconnected from the server by invoking the disconnect() method:
eio.disconnect()
For the asyncio client this is a coroutine:
await eio.disconnect()
When a client connection to the server is established, a few background tasks will be spawned to keep the connection alive and handle incoming events. The application running on the main thread is free to do any work, as this is not going to prevent the functioning of the Engine.IO client.
If the application does not have anything to do in the main thread and just wants to wait until the connection ends, it can call the wait() method:
eio.wait()
Or in the asyncio version:
await eio.wait()
For the convenience of the application, a helper function is provided to start a custom background task:
def my_background_task(my_argument)
# do some background work here!
pass eio.start_background_task(my_background_task, 123)
The arguments passed to this method are the background function and any positional or keyword arguments to invoke the function with.
Here is the asyncio version:
async def my_background_task(my_argument)
# do some background work here!
pass eio.start_background_task(my_background_task, 123)
Note that this function is not a coroutine, since it does not wait for the background function to end, but the background function is.
The sleep() method is a second convenience function that is provided for the benefit of applications working with background tasks of their own:
Or for asyncio:
await eio.sleep(2)
The single argument passed to the method is the number of seconds to sleep for.
To help you debug issues, the client can be configured to output logs to the terminal:
import engineio # standard Python eio = engineio.Client(logger=True) # asyncio eio = engineio.AsyncClient(logger=True)
The logger argument 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, unexpected disconnections and other issues.
This package contains two Engine.IO servers:
The methods in the two servers are the same, with the only difference that in the asyncio server most methods are implemented as coroutines.
To install the Python Engine.IO server use the following command:
pip install "python-engineio"
In addition to the server, you will need to select an asynchronous framework or server to use along with it. The list of supported packages is covered in the Deployment Strategies section.
An Engine.IO server is an instance of class engineio.Server. This instance can be transformed into a standard WSGI application by wrapping it with the engineio.WSGIApp class:
import engineio # create a Engine.IO server eio = engineio.Server() # wrap with a WSGI application app = engineio.WSGIApp(eio)
For asyncio based servers, the engineio.AsyncServer class provides the same functionality, but in a coroutine friendly format. If desired, The engineio.ASGIApp class can transform the server into a standard ASGI application:
# create a Engine.IO server eio = engineio.AsyncServer() # wrap with ASGI application app = engineio.ASGIApp(eio)
These two wrappers can also act as middlewares, forwarding any traffic that is not intended to the Engine.IO server to another application. This allows Engine.IO servers to integrate easily into existing WSGI or ASGI applications:
from wsgi import app # a Flask, Django, etc. application app = engineio.WSGIApp(eio, app)
The Engine.IO server can be configured to serve static files to clients. This is particularly useful to deliver HTML, CSS and JavaScript files to clients when this package is used without a companion web framework.
Static files are configured with a Python dictionary in which each key/value pair is a static file mapping rule. In its simplest form, this dictionary has one or more static file URLs as keys, and the corresponding files in the server as values:
static_files = {
'/': 'latency.html',
'/static/engine.io.js': 'static/engine.io.js',
'/static/style.css': 'static/style.css',
}
With this example configuration, when the server receives a request for / (the root URL) it will return the contents of the file latency.html in the current directory, and will assign a content type based on the file extension, in this case text/html.
Files with the .html, .css, .js, .json, .jpg, .png, .gif and .txt file extensions are automatically recognized and assigned the correct content type. For files with other file extensions or with no file extension, the application/octet-stream content type is used as a default.
If desired, an explicit content type for a static file can be given as follows:
static_files = {
'/': {'filename': 'latency.html', 'content_type': 'text/plain'},
}
It is also possible to configure an entire directory in a single rule, so that all the files in it are served as static files:
static_files = {
'/static': './public',
}
In this example any files with URLs starting with /static will be served directly from the public folder in the current directory, so for example, the URL /static/index.html will return local file ./public/index.html and the URL /static/css/styles.css will return local file ./public/css/styles.css.
If a URL that ends in a / is requested, then a default filename of index.html is appended to it. In the previous example, a request for the /static/ URL would return local file ./public/index.html. The default filename to serve for slash-ending URLs can be set in the static files dictionary with an empty key:
static_files = {
'/static': './public',
'': 'image.gif',
}
With this configuration, a request for /static/ would return local file ./public/image.gif. A non-standard content type can also be specified if needed:
static_files = {
'/static': './public',
'': {'filename': 'image.gif', 'content_type': 'text/plain'},
}
The static file configuration dictionary is given as the static_files argument to the engineio.WSGIApp or engineio.ASGIApp classes:
# for standard WSGI applications eio = engineio.Server() app = engineio.WSGIApp(eio, static_files=static_files) # for asyncio-based ASGI applications eio = engineio.AsyncServer() app = engineio.ASGIApp(eio, static_files=static_files)
The routing precedence in these two classes is as follows:
Note: static file serving is intended for development use only, and as such it lacks important features such as caching. Do not use in a production environment.
To responds to events triggered by the connection or the client, event Handler functions must be defined using the on decorator:
@eio.on('connect')
def on_connect(sid):
print('A client connected!')
@eio.on('message')
def on_message(sid, data):
print('I received a message!')
@eio.on('disconnect')
def on_disconnect(sid):
print('Client disconnected!')
For the asyncio server, event handlers can be regular functions as above, or can also be coroutines:
@eio.on('message')
async def on_message(sid, data):
print('I received a message!')
The argument given to the on decorator is the event name. The events that are supported are connect, message and disconnect. Note that the disconnect handler is invoked for client initiated disconnects, server initiated disconnects, or accidental disconnects, for example due to networking failures.
The sid argument passed into all the event handlers is a connection identifier for the client. All the events from a client will use the same sid value.
The connect handler is the place where the server can perform authentication. The value returned by this handler is used to determine if the connection is accepted or rejected. When the handler does not return any value (which is the same as returning None) or when it returns True the connection is accepted. If the handler returns False or any JSON compatible data type (string, integer, list or dictionary) the connection is rejected. A rejected connection triggers a response with a 401 status code.
The data argument passed to the 'message' event handler contains application-specific data provided by the client with the event.
The server can send a message to any client using the send() method:
eio.send(sid, {'foo': 'bar'})
Or in the case of asyncio, as a coroutine:
await eio.send(sid, {'foo': 'bar'})
The first argument provided to the method is the connection identifier for the recipient client. The second argument is the data that is passed on to the server. The data can be of type str, bytes, dict or list. The data included inside dictionaries and lists is also constrained to these types.
The send() method can be invoked inside an event handler as a response to a client event, or in any other part of the application, including in background tasks.
The server can maintain application-specific information in a user session dedicated to each connected client. Applications can use the user session to write any details about the user that need to be preserved throughout the life of the connection, such as usernames or user ids.
The save_session() and get_session() methods are used to store and retrieve information in the user session:
@eio.on('connect')
def on_connect(sid, environ):
username = authenticate_user(environ)
eio.save_session(sid, {'username': username})
@eio.on('message')
def on_message(sid, data):
session = eio.get_session(sid)
print('message from ', session['username'])
For the asyncio server, these methods are coroutines:
@eio.on('connect')
async def on_connect(sid, environ):
username = authenticate_user(environ)
await eio.save_session(sid, {'username': username})
@eio.on('message')
async def on_message(sid, data):
session = await eio.get_session(sid)
print('message from ', session['username'])
The session can also be manipulated with the session() context manager:
@eio.on('connect')
def on_connect(sid, environ):
username = authenticate_user(environ)
with eio.session(sid) as session:
session['username'] = username
@eio.on('message')
def on_message(sid, data):
with eio.session(sid) as session:
print('message from ', session['username'])
For the asyncio server, an asynchronous context manager is used:
@eio.on('connect')
def on_connect(sid, environ):
username = authenticate_user(environ)
async with eio.session(sid) as session:
session['username'] = username
@eio.on('message')
def on_message(sid, data):
async with eio.session(sid) as session:
print('message from ', session['username'])
Note: the contents of the user session are destroyed when the client disconnects.
At any time the server can disconnect a client from the server by invoking the disconnect() method and passing the sid value assigned to the client:
eio.disconnect(sid)
For the asyncio client this is a coroutine:
await eio.disconnect(sid)
For the convenience of the application, a helper function is provided to start a custom background task:
def my_background_task(my_argument)
# do some background work here!
pass eio.start_background_task(my_background_task, 123)
The arguments passed to this method are the background function and any positional or keyword arguments to invoke the function with.
Here is the asyncio version:
async def my_background_task(my_argument)
# do some background work here!
pass eio.start_background_task(my_background_task, 123)
Note that this function is not a coroutine, since it does not wait for the background function to end, but the background function is.
The sleep() method is a second convenience function that is provided for the benefit of applications working with background tasks of their own:
Or for asyncio:
await eio.sleep(2)
The single argument passed to the method is the number of seconds to sleep for.
To help you debug issues, the server can be configured to output logs to the terminal:
import engineio # standard Python eio = engineio.Server(logger=True) # asyncio eio = engineio.AsyncServer(logger=True)
The logger argument 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.
The following sections describe a variety of deployment strategies for Engine.IO servers.
aiohttp provides a framework with support for HTTP and WebSocket, based on asyncio. Support for this framework is limited to Python 3.5 and newer.
Instances of class engineio.AsyncServer will automatically use aiohttp for asynchronous operations if the library is installed. To request its use explicitly, the async_mode option can be given in the constructor:
eio = engineio.AsyncServer(async_mode='aiohttp')
A server configured for aiohttp must be attached to an existing application:
app = web.Application() eio.attach(app)
The aiohttp application can define regular routes that will coexist with the Engine.IO server. A typical pattern is to add routes that serve a client application and any associated static files.
The aiohttp application is then executed in the usual manner:
if __name__ == '__main__':
web.run_app(app)
Tornado is a web framework with support for HTTP and WebSocket. Support for this framework requires Python 3.5 and newer. Only Tornado version 5 and newer are supported, thanks to its tight integration with asyncio.
Instances of class engineio.AsyncServer will automatically use tornado for asynchronous operations if the library is installed. To request its use explicitly, the async_mode option can be given in the constructor:
eio = engineio.AsyncServer(async_mode='tornado')
A server configured for tornado must include a request handler for Engine.IO:
app = tornado.web.Application(
[
(r"/engine.io/", engineio.get_tornado_handler(eio)),
],
# ... other application options )
The tornado application can define other routes that will coexist with the Engine.IO server. A typical pattern is to add routes that serve a client application and any associated static files.
The tornado application is then executed in the usual manner:
app.listen(port) tornado.ioloop.IOLoop.current().start()
Sanic is a very efficient asynchronous web server for Python 3.5 and newer.
Instances of class engineio.AsyncServer will automatically use Sanic for asynchronous operations if the framework is installed. To request its use explicitly, the async_mode option can be given in the constructor:
eio = engineio.AsyncServer(async_mode='sanic')
A server configured for Sanic must be attached to an existing application:
app = Sanic() eio.attach(app)
The Sanic application can define regular routes that will coexist with the Engine.IO server. A typical pattern is to add routes that serve a client application and any associated static files to this application.
The Sanic application is then executed in the usual manner:
if __name__ == '__main__':
app.run()
It has been reported that the CORS support provided by the Sanic extension sanic-cors is incompatible with this package's own support for this protocol. To disable CORS support in this package and let Sanic take full control, initialize the server as follows:
eio = engineio.AsyncServer(async_mode='sanic', cors_allowed_origins=[])
On the Sanic side you will need to enable the CORS_SUPPORTS_CREDENTIALS setting in addition to any other configuration that you use:
app.config['CORS_SUPPORTS_CREDENTIALS'] = True
The engineio.ASGIApp class is an ASGI compatible application that can forward Engine.IO traffic to an engineio.AsyncServer instance:
eio = engineio.AsyncServer(async_mode='asgi') app = engineio.ASGIApp(eio)
The application can then be deployed with any ASGI compatible web server.
Eventlet is a high performance concurrent networking library for Python 2 and 3 that uses coroutines, enabling code to be written in the same style used with the blocking standard library functions. An Engine.IO server deployed with eventlet has access to the long-polling and WebSocket transports.
Instances of class engineio.Server will automatically use eventlet for asynchronous operations if the library is installed. To request its use explicitly, the async_mode option can be given in the constructor:
eio = engineio.Server(async_mode='eventlet')
A server configured for eventlet is deployed as a regular WSGI application using the provided engineio.WSGIApp:
app = engineio.WSGIApp(eio)
import eventlet
eventlet.wsgi.server(eventlet.listen(('', 8000)), app)
An alternative to running the eventlet WSGI server as above is to use gunicorn, a fully featured pure Python web server. The command to launch the application under gunicorn is shown below:
$ gunicorn -k eventlet -w 1 module:app
Due to limitations in its load balancing algorithm, gunicorn can only be used with one worker process, so the -w 1 option is required. Note that a single eventlet worker can handle a large number of concurrent clients.
Another limitation when using gunicorn is that the WebSocket transport is not available, because this transport it requires extensions to the WSGI standard.
Note: Eventlet provides a monkey_patch() function that replaces all the blocking functions in the standard library with equivalent asynchronous versions. While python-engineio does not require monkey patching, other libraries such as database drivers are likely to require it.
Gevent is another asynchronous framework based on coroutines, very similar to eventlet. An Engine.IO server deployed with gevent has access to the long-polling transport. If project gevent-websocket is installed, the WebSocket transport is also available. Note that when using the uWSGI server, the native WebSocket implementation of uWSGI can be used instead of gevent-websocket (see next section for details on this).
Instances of class engineio.Server will automatically use gevent for asynchronous operations if the library is installed and eventlet is not installed. To request gevent to be selected explicitly, the async_mode option can be given in the constructor:
# gevent alone or with gevent-websocket eio = engineio.Server(async_mode='gevent')
A server configured for gevent is deployed as a regular WSGI application using the provided engineio.WSGIApp:
from gevent import pywsgi
app = engineio.WSGIApp(eio)
pywsgi.WSGIServer(('', 8000), app).serve_forever()
If the WebSocket transport is installed, then the server must be started as follows:
from gevent import pywsgi
from geventwebsocket.handler import WebSocketHandler
app = engineio.WSGIApp(eio)
pywsgi.WSGIServer(('', 8000), app,
handler_class=WebSocketHandler).serve_forever()
An alternative to running the gevent WSGI server as above is to use gunicorn, a fully featured pure Python web server. The command to launch the application under gunicorn is shown below:
$ gunicorn -k gevent -w 1 module:app
Or to include WebSocket:
$ gunicorn -k geventwebsocket.gunicorn.workers.GeventWebSocketWorker -w 1 module: app
Same as with eventlet, due to limitations in its load balancing algorithm, gunicorn can only be used with one worker process, so the -w 1 option is required. Note that a single gevent worker can handle a large number of concurrent clients.
Note: Gevent provides a monkey_patch() function that replaces all the blocking functions in the standard library with equivalent asynchronous versions. While python-engineio does not require monkey patching, other libraries such as database drivers are likely to require it.
When using the uWSGI server in combination with gevent, the Engine.IO server can take advantage of uWSGI's native WebSocket support.
Instances of class engineio.Server will automatically use this option for asynchronous operations if both gevent and uWSGI are installed and eventlet is not installed. To request this asynchoronous mode explicitly, the async_mode option can be given in the constructor:
# gevent with uWSGI eio = engineio.Server(async_mode='gevent_uwsgi')
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 latency.py example on port 5000:
$ uwsgi --http :5000 --gevent 1000 --http-websockets --master --wsgi-file latency.py --callable app
While not comparable to eventlet and gevent in terms of performance, the Engine.IO server can also be configured to work with multi-threaded web servers that use standard Python threads. This is an ideal setup to use with development servers such as Werkzeug. Only the long-polling transport is currently available when using standard threads.
Instances of class engineio.Server will automatically use the threading mode if neither eventlet nor gevent are not installed. To request the threading mode explicitly, the async_mode option can be given in the constructor:
eio = engineio.Server(async_mode='threading')
A server configured for threading is deployed as a regular web application, using any WSGI complaint multi-threaded server. The example below deploys an Engine.IO application combined with a Flask web application, using Flask's development web server based on Werkzeug:
eio = engineio.Server(async_mode='threading') app = Flask(__name__) app.wsgi_app = engineio.WSGIApp(eio, app.wsgi_app) # ... Engine.IO and Flask handler functions ... if __name__ == '__main__':
app.run(threaded=True)
When using the threading mode, it is important to ensure that the WSGI server can handle multiple concurrent requests using threads, since a client can have up to two outstanding requests at any given time. The Werkzeug server is single-threaded by default, so the threaded=True option is required.
Note that servers that use worker processes instead of threads, such as gunicorn, do not support an Engine.IO server configured in threading mode.
Engine.IO is a stateful protocol, which makes horizontal scaling more difficult. To deploy a cluster of Engine.IO processes hosted on one or multiple servers the following conditions must be met:
For security reasons, this server enforces a same-origin policy by default. In practical terms, this means the following:
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.
This class implements a fully compliant Engine.IO web client with support for websocket and long-polling transports.
Example usage:
eio = engineio.Client()
eio.connect('http://localhost:5000')
Example usage:
# as a decorator:
@eio.on('connect')
def connect_handler():
print('Connection request')
# as a method:
def message_handler(msg):
print('Received message: ', msg)
eio.send('response')
eio.on('message', message_handler)
This is a utility function that applications can use to start a background task.
This function returns an object compatible with the Thread class in the Python standard library. The start() method on this object is already called by this function.
The possible values returned by this function are 'polling' and 'websocket'.
Client applications can use this function to block the main thread during the life of the connection.
This class implements a fully compliant Engine.IO web client with support for websocket and long-polling transports, compatible with the asyncio framework on Python 3.5 or newer.
Note: this method is a coroutine.
Example usage:
eio = engineio.Client()
await eio.connect('http://localhost:5000')
Note: this method is a coroutine.
Example usage:
# as a decorator:
@eio.on('connect')
def connect_handler():
print('Connection request')
# as a method:
def message_handler(msg):
print('Received message: ', msg)
eio.send('response')
eio.on('message', message_handler)
Note: this method is a coroutine.
Note: this method is a coroutine.
This is a utility function that applications can use to start a background task.
This function returns an object compatible with the Thread class in the Python standard library. The start() method on this object is already called by this function.
Note: this method is a coroutine.
The possible values returned by this function are 'polling' and 'websocket'.
Client applications can use this function to block the main thread during the life of the connection.
Note: this method is a coroutine.
This class implements a fully compliant Engine.IO web server with support for websocket and long-polling transports.
This is a utility function that applications can use to create an event without having to worry about using the correct call for the selected async mode.
This is a utility function that applications can use to create a queue without having to worry about using the correct call for the selected async mode.
This is a utility function that applications can use to work with a queue without having to worry about using the correct call for the selected async mode.
The return value is a dictionary. Modifications made to this dictionary are not guaranteed to be preserved unless save_session() is called, or when the session context manager is used.
This is the entry point of the Engine.IO application, using the same interface as a WSGI application. For the typical usage, this function is invoked by the Middleware instance, but it can be invoked directly when the middleware is not used.
This function returns the HTTP response body to deliver to the client as a byte sequence.
Example usage:
# as a decorator:
@eio.on('connect')
def connect_handler(sid, environ):
print('Connection request')
if environ['REMOTE_ADDR'] in blacklisted:
return False # reject
# as a method:
def message_handler(sid, msg):
print('Received message: ', msg)
eio.send(sid, 'response')
eio.on('message', message_handler)
The handler function receives the sid (session ID) for the client as first argument. The 'connect' event handler receives the WSGI environment as a second argument, and can return False to reject the connection. The 'message' handler receives the message payload as a second argument. The 'disconnect' handler does not take a second argument.
This is a context manager that returns the user session dictionary for the client. Any changes that are made to this dictionary inside the context manager block are saved back to the session. Example usage:
@eio.on('connect')
def on_connect(sid, environ):
username = authenticate_user(environ)
if not username:
return False
with eio.session(sid) as session:
session['username'] = username
@eio.on('message')
def on_message(sid, msg):
with eio.session(sid) as session:
print('received message from ', session['username'])
This is a utility function that applications can use to put a task to sleep without having to worry about using the correct call for the selected async mode.
This is a utility function that applications can use to start a background task using the method that is compatible with the selected async mode.
This function returns an object compatible with the Thread class in the Python standard library. The start() method on this object is already called by this function.
The two possible values returned by this function are 'polling' and 'websocket'.
This class implements a fully compliant Engine.IO web server with support for websocket and long-polling transports, compatible with the asyncio framework on Python 3.5 or newer.
This is a utility function that applications can use to create an event without having to worry about using the correct call for the selected async mode. For asyncio based async modes, this returns an instance of asyncio.Event.
This is a utility function that applications can use to create a queue without having to worry about using the correct call for the selected async mode. For asyncio based async modes, this returns an instance of asyncio.Queue.
Note: this method is a coroutine.
This is a utility function that applications can use to work with a queue without having to worry about using the correct call for the selected async mode. For asyncio based async modes, this returns an instance of asyncio.QueueEmpty.
The return value is a dictionary. Modifications made to this dictionary are not guaranteed to be preserved. If you want to modify the user session, use the session context manager instead.
This is the entry point of the Engine.IO application. This function returns the HTTP response to deliver to the client.
Note: this method is a coroutine.
Example usage:
# as a decorator:
@eio.on('connect')
def connect_handler(sid, environ):
print('Connection request')
if environ['REMOTE_ADDR'] in blacklisted:
return False # reject
# as a method:
def message_handler(sid, msg):
print('Received message: ', msg)
eio.send(sid, 'response')
eio.on('message', message_handler)
The handler function receives the sid (session ID) for the client as first argument. The 'connect' event handler receives the WSGI environment as a second argument, and can return False to reject the connection. The 'message' handler receives the message payload as a second argument. The 'disconnect' handler does not take a second argument.
Note: this method is a coroutine.
This is a context manager that returns the user session dictionary for the client. Any changes that are made to this dictionary inside the context manager block are saved back to the session. Example usage:
@eio.on('connect')
def on_connect(sid, environ):
username = authenticate_user(environ)
if not username:
return False
with eio.session(sid) as session:
session['username'] = username
@eio.on('message')
def on_message(sid, msg):
async with eio.session(sid) as session:
print('received message from ', session['username'])
This is a utility function that applications can use to put a task to sleep without having to worry about using the correct call for the selected async mode.
Note: this method is a coroutine.
This is a utility function that applications can use to start a background task using the method that is compatible with the selected async mode.
The return value is a asyncio.Task object.
The two possible values returned by this function are 'polling' and 'websocket'.
This middleware dispatches traffic to an Engine.IO application. It can also serve a list of static files to the client, or forward unrelated HTTP traffic to another WSGI application.
Example usage:
import engineio
import eventlet
eio = engineio.Server()
app = engineio.WSGIApp(eio, static_files={
'/': {'content_type': 'text/html', 'filename': 'index.html'},
'/index.html': {'content_type': 'text/html',
'filename': 'index.html'},
})
eventlet.wsgi.server(eventlet.listen(('', 8000)), app)
This middleware dispatches traffic to an Engine.IO application. It can also serve a list of static files to the client, or forward unrelated HTTP traffic to another ASGI application.
Example usage:
import engineio
import uvicorn
eio = engineio.AsyncServer()
app = engineio.ASGIApp(eio, static_files={
'/': {'content_type': 'text/html', 'filename': 'index.html'},
'/index.html': {'content_type': 'text/html',
'filename': 'index.html'},
})
uvicorn.run(app, '127.0.0.1', 5000)
Miguel Grinberg
2018, Miguel Grinberg
| December 24, 2020 |