Running a Bokeh Server

Purpose

The purpose of the Bokeh server is to make it easy for Python users to create interactive web applications that can connect front-end UI events to real, running Python code.

The architecture of Bokeh is such that high-level “model objects” (representing things like plots, ranges, axes, glyphs, etc.) are created in Python, and then converted to a JSON format that is consumed by the client library, BokehJS. (See Defining Key Concepts for a more detailed discussion.) By itself, this flexible and decoupled design offers advantages, for instance it is easy to have other languages (R, Scala, Lua, …) drive the exact same Bokeh plots and visualizations in the browser.

However, if it were possible to keep the “model objects” in python and in the browser in sync with one another, then more additional and powerful possibilities immediately open up:

  • respond to UI and tool events generated in a browser with computations or queries using the full power of python

  • automatically push server-side updates to the UI (i.e. widgets or plots in a browser)

  • use periodic, timeout, and asynchronous callbacks to drive streaming updates

This capability to synchronize between python and the browser is the main purpose of the Bokeh Server.


The simple example below, embedded from demo.bokeh.org, illustrates this.

When the controls are manipulated, their new values are automatically synced in the Bokeh server. Callbacks are triggered that also update the data for the plot in the server. These changes are automatically synced back to the browser, and the plot updates.

Use Case Scenarios

Now that we know what the Bokeh server is for, and what it is capable of doing, it’s worth considering a few different scenarios when you might want to use a Bokeh Server.

Local or Individual Use

One way that you might want to use the Bokeh server is during exploratory data analysis, possibly in a Jupyter notebook. Alternatively, you might want to create a small app that you can run locally, or that you can send to colleagues to run locally. The Bokeh server is very useful and easy to use in this scenario. Both of the methods here below can be used effectively:

For the most flexible approach, that could transition most directly to a deployable application, it is suggested to follow the techniques in Building Bokeh Applications.

Creating Deployable Applications

Another way that you might want to use the Bokeh server is to publish interactive data visualizations and applications that can be viewed and used by a wider audience (perhaps on the internet, or perhaps on an internal company network). The Bokeh Server is also well-suited to this usage, and you will want to first consult the sections:

Shared Publishing

Both of the scenarios above involve a single creator making applications on the server, either for their own local use, or for consumption by a larger audience. Another scenario is the case where a group of several creators all want publish different applications to the same server. This is not a good use-case for single Bokeh server. Because it is possible to create applications that execute arbitrary python code, process isolation and security concerns make this kind of shared tenancy prohibitive.

In order to support this kind of multi-creator, multi-application environment, one approach is to build up infrastructure that can run as many Bokeh servers as-needed, either on a per-app, or at least a per-user basis. It is possible that we may create a public service to enable just this kind of usage in the future, and it would also certainly be possible for third parties to build their own private infrastructure to do so as well, but that is beyond the scope of this User’s Guide.

Another possibility is to have a single centrally created app (perhaps by an organization), that can access data or other artifacts published by many different people (possibly with access controls). This sort of scenario is possible with the Bokeh server, but often involves integrating a Bokeh server with other web application frameworks.

Building Bokeh Applications

By far the most flexible way to create interactive data visualizations using the Bokeh server is to create Bokeh Applications, and serve them with the bokeh serve command. In this scenario, a Bokeh server uses the application code to create sessions and documents for all browsers that connect:

../../_images/bokeh_serve.svg

A Bokeh server (left) uses Application code to create Bokeh Documents. Every new connection from a browser (right) results in the Bokeh server creating a new document, just for that session.

The application code is executed in the Bokeh server every time a new connection is made, to create the new Bokeh Document that will be synced to the browser. The application code also sets up any callbacks that should be run whenever properties such as widget values are changes.

There are a few different ways to provide the application code.

Single module format

Let’s look again at a complete example and then examine some specific parts in more detail:

# myapp.py

from random import random

from bokeh.layouts import column
from bokeh.models import Button
from bokeh.palettes import RdYlBu3
from bokeh.plotting import figure, curdoc

# create a plot and style its properties
p = figure(x_range=(0, 100), y_range=(0, 100), toolbar_location=None)
p.border_fill_color = 'black'
p.background_fill_color = 'black'
p.outline_line_color = None
p.grid.grid_line_color = None

# add a text renderer to our plot (no data yet)
r = p.text(x=[], y=[], text=[], text_color=[], text_font_size="26px",
           text_baseline="middle", text_align="center")

i = 0

ds = r.data_source

# create a callback that will add a number in a random location
def callback():
    global i

    # BEST PRACTICE --- update .data in one step with a new dict
    new_data = dict()
    new_data['x'] = ds.data['x'] + [random()*70 + 15]
    new_data['y'] = ds.data['y'] + [random()*70 + 15]
    new_data['text_color'] = ds.data['text_color'] + [RdYlBu3[i%3]]
    new_data['text'] = ds.data['text'] + [str(i)]
    ds.data = new_data

    i = i + 1

# add a button widget and configure with the call back
button = Button(label="Press Me")
button.on_click(callback)

# put the button and plot in a layout and add to the document
curdoc().add_root(column(button, p))

Notice that we have not specified an output or connection method anywhere in this code. It is a simple script that creates and updates objects. The flexibility of the bokeh command line tool means that we can defer output options until the end. We could, e.g., run bokeh json myapp.py to get a JSON serialized version of the application. But in this case, we would like to run the app on a Bokeh server, so we execute:

bokeh serve --show myapp.py

The --show option will cause a browser to open up a new tab automatically to the address of the running application, which in this case is:

http://localhost:5006/myapp

If you have only one application, the server root will redirect to it. Otherwise, You can see an index of all running applications at the server root:

http://localhost:5006/

This index can be disabled with the --disable-index option, and the redirect behavior can be disabled with the --disable-index-redirect option.

In addition to creating Bokeh applications from single python files, it is also possible to create applications from directories.

Directory format

Bokeh applications may also be created by creating and populating a filesystem directory with the appropriate files. To start a directory application in a directory myapp, execute bokeh serve with the name of the directory, for instance:

bokeh serve --show myapp

At a minimum, the directory must contain a main.py that constructs a Document for the Bokeh Server to serve:

myapp
   |
   +---main.py

The full set of files that Bokeh server knows about is:

myapp
   |
   +---__init__.py
   +---app_hooks.py
   +---main.py
   +---request_handler.py
   +---static
   +---theme.yaml
   +---templates
        +---index.html

The optional components are

  • An __init__.py file that marks this directory as a package. Package relative imports, e.g. from . import mymod and from .mymod import func will be possible.

  • A request_handler.py file that allows declaring an optional function which processes the HTTP request and returns a dictionary of items to be included in the session token, as described in Request Handler Hooks.

  • A app_hooks.py file that allows optional callbacks to be triggered at different stages of application execution, as described in Lifecycle Hooks and Request Handler Hooks.

  • A static subdirectory that can be used to serve static resources associated with this application.

  • A theme.yaml file that declaratively defines default attributes to be applied to Bokeh model types.

  • A templates subdirectory with index.html Jinja template file. The directory may contain additional Jinja templates for index.html to refer to. The template should have the same parameters as the FILE template. See Customising the Application’s Jinja Template for more details.

When executing your main.py Bokeh server ensures that the standard __file__ module attribute works as you would expect. So it is possible to include data files or custom user defined models in your directory however you like.

Additionally, the application directory is also added to sys.path so that Python modules in the application directory may be easily imported. However, if an __init__.py is present in the directory then the app is usable as a package, and standard package-relative imports will also work.

An example might be:

myapp
   |
   +---__init__.py
   |
   +---app_hooks.py
   +---data
   |    +---things.csv
   |
   +---helpers.py
   +---main.py
   |---models
   |    +---custom.js
   |
   +---request_handler.py
   +---static
   |    +---css
   |    |    +---special.css
   |    |
   |    +---images
   |    |    +---foo.png
   |    |    +---bar.png
   |    |
   |    +---js
   |        +---special.js
   |
   |---templates
   |    +---index.html
   |
   +---theme.yaml

In this case you might have code similar to:

from os.path import dirname, join
from .helpers import load_data

load_data(join(dirname(__file__), 'data', 'things.csv'))

And similar code to load the JavaScript implementation for a custom model from models/custom.js

Customising the Application’s Jinja Template

As described above in Directory format, you can override the default Jinja template used by the Bokeh server to generate the HTML code served to the user’s browser.

This opens up the possibility of managing the layout of the application in the client’s browser using CSS, as well as making use of other Javascript libraries alongside BokehJS.

See the Jinja Project Documentation for more details on how Jinja templating works.

Embedding Figures in the Template

In the main thread of the Bokeh application, i.e. main.py, any Bokeh figures that are going to be referenced in the templated code need to have their name attribute set, and be added to the current document root.

from bokeh.plotting import curdoc

# templates can refer to a configured name value
plot = figure(name="bokeh_jinja_figure")

curdoc().add_root(plot)

Then, in the corresponding Jinja template code, the figure may be referenced via the roots template parameter, using the figure’s name, i.e.

{% extends base %}

{% block contents %}
<div>
    {{ embed(roots.bokeh_jinja_figure) }}
</div>
{% endblock %}

Defining Custom Variables

Custom variables can be passed to the template via the curdoc().template_variables dictionary in place:

# set a new single key/value
curdoc().template_variables["user_id"] = user_id

# or update multiple at once
curdoc().template_variables.update(first_name="Mary", last_name="Jones")

Then, in the corresponding Jinja template code, the variables may be referenced directly:

{% extends base %}

{% block contents %}
<div>
    <p> Hello {{ user_id }}, AKA '{{ last_name }}, {{ first_name }}'! </p>
</div>
{% endblock %}

Accessing the HTTP Request

When a session is created for a Bokeh application, the session context is made available as curdoc().session_context. The most useful function of the session context is to make the Tornado HTTP request object available to the application as session_context.request. Due to an incompatibility issue with the usage of --num-procs the HTTP request is not made available directly. Instead only the arguments attribute is available in full and only the subset of cookies and headers which are allowed by the --include-headers, --exclude-headers, --include-cookies and --exclude-cookies are made available. Attempting to access any other attribute on request will result in an error.

Any additional attributes on the request can be made accessible as described in Request Handler Hooks.

As an example, the following code will access the request arguments to set a value for a variable N (perhaps controlling the number of points in a plot):

# request.arguments is a dict that maps argument names to lists of strings,
# e.g, the query string ?N=10 will result in {'N': [b'10']}

args = curdoc().session_context.request.arguments

try:
  N = int(args.get('N')[0])
except:
  N = 200

Warning

The request object is provided so that values such as arguments may be easily inspected. Calling any of the Tornado methods such as finish() or writing directly to request.connection is unsupported and will result in undefined behavior.

Request Handler Hooks

Since the full tornado HTTP request is not guaranteed to be available on the process serving the session, a custom handler can be defined to make additional information available.

To define such a hook, you must create your application in Directory format, and include a designated file called request_handler.py in the directory. In this file you must include a conventionally named process_request function:

def process_request(request):
    ''' If present this function is called when the HTTP request arrives. '''
    return {}

The handler is given the Tornado HTTP request and can process the request and return a dictionary which will be made available on curdoc().session_context.token_payload. In this way additional information can be made available to work around some of the issues when --num-procs is used.

Callbacks and Events

Before jumping in to callbacks and events specifically in the context of the Bokeh Server, it’s worth discussing different use-cases for callbacks in general.

JavaScript Callbacks in the Browser

Regardless of whether there is a Bokeh Server involved, it is possible to create callbacks that execute in the browser, using CustomJS and other methods. See JavaScript Callbacks for more detailed information and examples.

It is critical to note that no python code is ever executed when a CustomJS callback is used. This is true even when the call back is supplied as python code to be translated to JavaScript. A CustomJS callback is only executed inside the browser’s JavaScript interpreter, and thus can only directly interact with JavaScript data and functions (e.g., BokehJS models).

Python Callbacks with Jupyter Interactors

If you are working in the Jupyter Notebook, it is possible to use Jupyter interactors to quickly create simple GUI forms automatically. Updates to the widgets in the GUI can trigger python callback functions that execute in the Jupyter Python kernel. It is often useful to have these callbacks call push_notebook() to push updates to displayed plots. For more detailed information, see Jupyter Interactors.

Note

It is currently possible to push updates from python, to BokehJS (i.e., to update plots, etc.) using push_notebook(). To add two-way communication (e.g. to have a range or selection update trigger a python callback) embed a Bokeh Server in the notebook. See examples/howto/server_embed/notebook_embed.ipynb

Updating From Threads

If the app needs to perform blocking computation, it is possible to perform that work in a separate thread. However, updates to the Document must be scheduled via a next-tick callback. The callback will execute as soon as possible on the next iteration of the Tornado event loop, and will automatically acquire necessary locks to update the document state safely.

Warning

The ONLY safe operations to perform on a document from a different thread is add_next_tick_callback() and remove_next_tick_callback()

It is important to emphasize that the document update must be scheduled in a “next tick callback”. Any usage that directly updates the document state from another thread, either by calling other document methods, or by setting properties on Bokeh models, risks data and protocol corruption.

It is also important to save a local copy of curdoc() so that all threads have access to the same document. This is illustrated in the example below:

from functools import partial
from random import random
from threading import Thread
import time

from bokeh.models import ColumnDataSource
from bokeh.plotting import curdoc, figure

from tornado import gen

# this must only be modified from a Bokeh session callback
source = ColumnDataSource(data=dict(x=[0], y=[0]))

# This is important! Save curdoc() to make sure all threads
# see the same document.
doc = curdoc()

@gen.coroutine
def update(x, y):
    source.stream(dict(x=[x], y=[y]))

def blocking_task():
    while True:
        # do some blocking computation
        time.sleep(0.1)
        x, y = random(), random()

        # but update the document from callback
        doc.add_next_tick_callback(partial(update, x=x, y=y))

p = figure(x_range=[0, 1], y_range=[0,1])
l = p.circle(x='x', y='y', source=source)

doc.add_root(p)

thread = Thread(target=blocking_task)
thread.start()

To see this example in action, save it to a python file, e.g. testapp.py and then execute

bokeh serve --show testapp.py

Warning

There is currently no locking around adding next tick callbacks to documents. It is recommended that at most one thread add callbacks to the document. It is planned to add more fine grained locking to callback methods in the future.

Updating from Unlocked Callbacks

Normally Bokeh session callbacks recursively lock the document until all future work they initiate is completed. However, you may want to drive blocking computations from callbacks using Tornado’s ThreadPoolExecutor in an asynchronous callback. This can work, but requires the Bokeh provided without_document_lock() decorator to suppress the normal locking behavior.

As with the thread example above, all actions that update document state must go through a next-tick callback.

The following example demonstrates an application that drives a blocking computation from one unlocked Bokeh session callback, by yielding to a blocking function that runs on the thread pool executor and updates by using a next-tick callback. The example also updates the state simply from a standard locked session callback on a different update rate.

from functools import partial
import time

from concurrent.futures import ThreadPoolExecutor
from tornado import gen

from bokeh.document import without_document_lock
from bokeh.models import ColumnDataSource
from bokeh.plotting import curdoc, figure

source = ColumnDataSource(data=dict(x=[0], y=[0], color=["blue"]))

i = 0

doc = curdoc()

executor = ThreadPoolExecutor(max_workers=2)

def blocking_task(i):
    time.sleep(1)
    return i

# the unlocked callback uses this locked callback to safely update
@gen.coroutine
def locked_update(i):
    source.stream(dict(x=[source.data['x'][-1]+1], y=[i], color=["blue"]))

# this unlocked callback will not prevent other session callbacks from
# executing while it is in flight
@gen.coroutine
@without_document_lock
def unlocked_task():
    global i
    i += 1
    res = yield executor.submit(blocking_task, i)
    doc.add_next_tick_callback(partial(locked_update, i=res))

@gen.coroutine
def update():
    source.stream(dict(x=[source.data['x'][-1]+1], y=[i], color=["red"]))

p = figure(x_range=[0, 100], y_range=[0,20])
l = p.circle(x='x', y='y', color='color', source=source)

doc.add_periodic_callback(unlocked_task, 1000)
doc.add_periodic_callback(update, 200)
doc.add_root(p)

As before, you can run this example by saving to a python file and running bokeh serve on it.

Lifecycle Hooks

Sometimes it is desirable to have code execute at specific times in a server or session lifetime. For instance, if you are using a Bokeh Server along side a Django server, you would need to call django.setup() once, as each Bokeh server starts, to initialize Django properly for use by Bokeh application code.

Bokeh provides this capability through a set of Lifecycle Hooks. To use these hooks, you must create your application in Directory format, and include a designated file called app_hooks.py in the directory. In this file you can include any or all of the following conventionally named functions:

def on_server_loaded(server_context):
    ''' If present, this function is called when the server first starts. '''
    pass

def on_server_unloaded(server_context):
    ''' If present, this function is called when the server shuts down. '''
    pass

def on_session_created(session_context):
    ''' If present, this function is called when a session is created. '''
    pass

def on_session_destroyed(session_context):
    ''' If present, this function is called when a session is closed. '''
    pass

Additionally, on_session_destroyed lifecycle hooks may also be defined directly on the Document being served. Since the task of cleaning up after a user closes a session is common, e.g. to shut down a database connection, this provides an easy route to performing such actions without bundling a separate file. To declare such a callback define a function and register it with the Document.on_session_destroyed method:

doc = Document()

def cleanup_session(session_context):
    ''' This function is called when a session is closed. '''
    pass

doc.on_session_destroyed(cleanup_session)

Besides the “lifecycle” hooks above, you may also define a “request hooks” for accessing the HTTP request users made. See Request Handler Hooks for full details.

Embedding Bokeh Server as a Library

It can be useful to embed the Bokeh Server in a larger Tornado application, or the Jupyter notebook, and use the already existing Tornado IOloop. Here is the basis of how to integrate Bokeh in such a scenario:

from bokeh.server.server import Server

server = Server(
    bokeh_applications,  # list of Bokeh applications
    io_loop=loop,        # Tornado IOLoop
    **server_kwargs      # port, num_procs, etc.
)

# start timers and services and immediately return
server.start()

It is also possible to create and control an IOLoop directly. This can be useful to create standalone “normal” python scripts that serve Bokeh apps, or to embed a Bokeh application into a framework like Flask or Django without having to run a separate Bokeh server process. Some examples of this technique can be found in the examples directory:

Also note that most every command line argument for bokeh serve has a corresponding keyword argument to Server. For instance, setting the –allow-websocket-origin command line argument is equivalent to passing allow_websocket_origin as a parameter.

Connecting with bokeh.client

There is also a client API for interacting directly with a Bokeh Server. The client API can be used to make modifications Bokeh documents in existing sessions in a Bokeh server.

../../_images/bokeh_serve_client.svg

Typically web browsers make connections to a Bokeh server, but it is possible to connect from python by using the bokeh.client module.

This can be useful, for example, to make user-specific customizations to a Bokeh app that is embedded by another web framework such as Flask or Django. An example of this is shown below. In this scenario, the “sliders” example is running separately, e.g. via bokeh serve sliders.py. A Flask endpoint embeds the sliders app, but changes the plot title before passing to the user:

from flask import Flask, render_template

from bokeh.client import pull_session
from bokeh.embed import server_session

app = Flask(__name__)

@app.route('/', methods=['GET'])
def bkapp_page():

    with pull_session(url="http://localhost:5006/sliders") as session:

        # update or customize that session
        session.document.roots[0].children[1].title.text = "Special Sliders For A Specific User!"

        # generate a script to load the customized session
        script = server_session(session_id=session.id, url='http://localhost:5006/sliders')

        # use the script in the rendered page
        return render_template("embed.html", script=script, template="Flask")

if __name__ == '__main__':
    app.run(port=8080)

Warning

It is possible to use bokeh.client to build up apps “from scratch”, outside a Bokeh server, including running and servicing callbacks by making a blocking call to session.loop_until_closed in the external Python process using bokeh.client. This usage has a number of inherent technical disadvantages, and should be considered unsupported.

Deployment Scenarios

With an application we are developing, we can run it locally any time we want to interact with it. To share it with other people who are able to install the required python stack, we can share the application with them, and let them run it locally themselves in the same manner. However, we might also want to deploy the application in a way that other people can access it as a service:

  • without having to install all of the prerequisites

  • without needing to have the source code

  • like any other webpage

This section describes some of the considerations that arise when deploying Bokeh server applications as a service for others to use.

Standalone Bokeh Server

First, it is possible to simply run the Bokeh server on a network for users to interact with directly. Depending on the computational burden of your application code, the number of users, the power of the machine used to run on, etc., this could be a simple and immediate option for deployment an internal network.

However, it is often the case that there are needs around authentication, scaling, and uptime. In these cases, more sophisticated deployment configurations are needed. In the following sections we discuss some of these considerations.

SSH Tunnels

It may be convenient or necessary to run a standalone instance of the Bokeh server on a host to which direct access cannot be allowed. In such cases, SSH can be used to “tunnel” to the server.

In the simplest scenario, the Bokeh server will run on one host and will be accessed from another location, e.g., a laptop, with no intermediary machines.

Run the server as usual on the remote host:

bokeh server

Next, issue the following command on the local machine to establish an SSH tunnel to the remote host:

ssh -NfL localhost:5006:localhost:5006 user@remote.host

Replace user with your username on the remote host and remote.host with the hostname/IP address of the system hosting the Bokeh server. You may be prompted for login credentials for the remote system. After the connection is set up you will be able to navigate to localhost:5006 as though the Bokeh server were running on the local machine.

The second, slightly more complicated case occurs when there is a gateway between the server and the local machine. In that situation a reverse tunnel must be established from the server to the gateway. Additionally the tunnel from the local machine will also point to the gateway.

Issue the following commands on the remote host where the Bokeh server will run:

nohup bokeh server &
ssh -NfR 5006:localhost:5006 user@gateway.host

Replace user with your username on the gateway and gateway.host with the hostname/IP address of the gateway. You may be prompted for login credentials for the gateway.

Now set up the other half of the tunnel, from the local machine to the gateway. On the local machine:

ssh -NfL localhost:5006:localhost:5006 user@gateway.host

Again, replace user with your username on the gateway and gateway.host with the hostname/IP address of the gateway. You should now be able to access the Bokeh server from the local machine by navigating to localhost:5006 on the local machine, as if the Bokeh server were running on the local machine. You can even set up client connections from a Jupyter notebook running on the local machine.

Note

We intend to expand this section with more guidance for other tools and configurations. If have experience with other web deployment scenarios and wish to contribute your knowledge here, please contact us on https://discourse.bokeh.org

SSL Termination

A Bokeh server can be configure to terminate SSL connections (i.e. to service secure HTTPS and WSS sessions) directly. At a minimum, the --ssl-certfile argument must be supplied. The value must be the path to a single file in PEM format containing the certificate as well as any number of CA certificates needed to establish the certificate’s authenticity:

bokeh serve --ssl-certfile /path/to/cert.pem

The path to the certificate file may also be supplied by setting the environment variable BOKEH_SSL_CERTFILE.

If the private key is stored separately, its location may be supplied by setting the --ssl-keyfile command line argument, or by setting the BOKEH_SSL_KEYFILE environment variable. If a password is required for the private key, it should be supplied by setting the BOKEH_SSL_PASSWORD environment variable.

Alternatively, you may wish to run a Bokeh server behind a proxy, and have the proxy terminate SSL. That scenario is described in the next section.

Basic Reverse Proxy Setup

If the goal is to serve an web application to the general Internet, it is often desirable to host the application on an internal network, and proxy connections to it through some dedicated HTTP server. This sections provides guidance for basic configuration behind some common reverse proxies.

Nginx

One very common HTTP and reverse-proxying server is Nginx. A sample server configuration block is shown below:

server {
    listen 80 default_server;
    server_name _;

    access_log  /tmp/bokeh.access.log;
    error_log   /tmp/bokeh.error.log debug;

    location / {
        proxy_pass http://127.0.0.1:5100;
        proxy_set_header Upgrade $http_upgrade;
        proxy_set_header Connection "upgrade";
        proxy_http_version 1.1;
        proxy_set_header X-Forwarded-For $proxy_add_x_forwarded_for;
        proxy_set_header Host $host:$server_port;
        proxy_buffering off;
    }

}

The above server block sets up Nginx to proxy incoming connections to 127.0.0.1 on port 80 to 127.0.0.1:5100 internally. To work in this configuration, we will need to use some of the command line options to configure the Bokeh Server. In particular we need to use --port to specify that the Bokeh Server should listen itself on port 5100.

bokeh serve myapp.py --port 5100

Note that in the basic server block above we have not configured any special handling for static resources, e.g., the Bokeh JS and CSS files. This means that these files are served directly by the Bokeh server itself. While this works, it places an unnecessary additional load on the Bokeh server, since Nginx has a fast static asset handler. To utilize Nginx to serve Bokeh’s static assets, you can add a new stanza inside the server block above, similar to this:

location /static {
    alias /path/to/bokeh/server/static;
}

Be careful that the file permissions of the Bokeh resources are accessible to whatever user account is running the Nginx server process. Alternatively, you can copy the resources to a global static directory during your deployment process.

Apache

Another common HTTP server and proxy is Apache. Here is sample configuration for running a Bokeh server behind Apache:

<VirtualHost *:80>
    ServerName localhost

    CustomLog "/path/to/logs/access_log" combined
    ErrorLog "/path/to/logs/error_log"

    ProxyPreserveHost On
    ProxyPass /myapp/ws ws://127.0.0.1:5100/myapp/ws
    ProxyPassReverse /myapp/ws ws://127.0.0.1:5100/myapp/ws

    ProxyPass /myapp http://127.0.0.1:5100/myapp/
    ProxyPassReverse /myapp http://127.0.0.1:5100/myapp/

    <Directory />
        Require all granted
        Options -Indexes
    </Directory>

    Alias /static /path/to/bokeh/server/static
    <Directory /path/to/bokeh/server/static>
        # directives to effect the static directory
        Options +Indexes
    </Directory>

</VirtualHost>

The above configuration aliases /static to the location of the Bokeh static resources directory, however it is also possible (and probably preferable) to copy the Bokeh static resources to whatever standard static files location is configured for Apache as part of the deployment.

Note that you may also need to enable some modules for the above configuration:

a2enmod proxy
a2enmod proxy_http
a2enmod proxy_wstunnel
apache2ctl restart

These might need to be run with sudo, depending on your system.

As before, you would run the Bokeh server with the command:

bokeh serve myapp.py --port 5100

Reverse Proxying with Nginx and SSL

If you would like to deploy a Bokeh Server behind an SSL-terminated Nginx proxy, then a few additional customizations are needed. In particular, the Bokeh server must be configured with the --use-xheaders flag:

bokeh serve myapp.py --port 5100 --use-xheaders

The --use-xheaders option causes Bokeh to override the remote IP and URI scheme/protocol for all requests with X-Real-Ip, X-Forwarded-For, X-Scheme, X-Forwarded-Proto headers when they are available.

You must also customize Nginx. In particular, you must configure Nginx to send the X-Forwarded-Proto header, as well as configure Nginx for SSL termination. Optionally, you may want to redirect all HTTP traffic to HTTPS. The complete details of this configuration (e.g. how and where to install SSL certificates and keys) will vary by platform, but a reference nginx.conf is provided below:

# redirect HTTP traffic to HTTPS (optional)
server {
    listen      80;
    server_name foo.com;
    return      301 https://$server_name$request_uri;
}

server {
    listen      443 default_server;
    server_name foo.com;

    # add Strict-Transport-Security to prevent man in the middle attacks
    add_header Strict-Transport-Security "max-age=31536000";

    ssl on;

    # SSL installation details will vary by platform
    ssl_certificate /etc/ssl/certs/my-ssl-bundle.crt;
    ssl_certificate_key /etc/ssl/private/my_ssl.key;

    # enables all versions of TLS, but not SSLv2 or v3 which are deprecated.
    ssl_protocols TLSv1 TLSv1.1 TLSv1.2;

    # disables all weak ciphers
    ssl_ciphers "ECDHE-RSA-AES256-GCM-SHA384:ECDHE-RSA-AES128-GCM-SHA256:DHE-RSA-AES256-GCM-SHA384:DHE-RSA-AES128-GCM-SHA256:ECDHE-RSA-AES256-SHA384:ECDHE-RSA-AES128-SHA256:ECDHE-RSA-AES256-SHA:ECDHE-RSA-AES128-SHA:DHE-RSA-AES256-SHA256:DHE-RSA-AES128-SHA256:DHE-RSA-AES256-SHA:DHE-RSA-AES128-SHA:ECDHE-RSA-DES-CBC3-SHA:EDH-RSA-DES-CBC3-SHA:AES256-GCM-SHA384:AES128-GCM-SHA256:AES256-SHA256:AES128-SHA256:AES256-SHA:AES128-SHA:DES-CBC3-SHA:HIGH:!aNULL:!eNULL:!EXPORT:!DES:!MD5:!PSK:!RC4";

    ssl_prefer_server_ciphers on;

    location / {
        proxy_pass http://127.0.0.1:5100;
        proxy_set_header Upgrade $http_upgrade;
        proxy_set_header Connection "upgrade";
        proxy_http_version 1.1;
        proxy_set_header X-Forwarded-Proto $scheme;
        proxy_set_header X-Forwarded-For $proxy_add_x_forwarded_for;
        proxy_set_header Host $host:$server_port;
        proxy_buffering off;
    }

}

This configuration will proxy all incoming HTTPS connections to foo.com to a Bokeh server running internally on http://127.0.0.1:5100.

Load Balancing with Nginx

The architecture of the Bokeh server is specifically designed to be scalable—by and large, if you need more capacity, you simply run additional servers. Often in this situation it is desired to run all the Bokeh server instances behind a load balancer, so that new connections are distributed amongst the individual servers.

../../_images/bokeh_serve_scale.svg

The Bokeh server is horizontally scalable. To add more capacity, more servers can be run behind a load balancer.

Nginx offers a load balancing capability. We will describe some of the basics of one possible configuration, but please also refer to the Nginx load balancer documentation. For instance, there are various different strategies available for choosing what server to connect to next.

First we need to add an upstream stanza to our NGinx configuration, typically above the server stanza. This section looks something like:

upstream myapp {
    least_conn;                 # Use Least Connections strategy
    server 127.0.0.1:5100;      # Bokeh Server 0
    server 127.0.0.1:5101;      # Bokeh Server 1
    server 127.0.0.1:5102;      # Bokeh Server 2
    server 127.0.0.1:5103;      # Bokeh Server 3
    server 127.0.0.1:5104;      # Bokeh Server 4
    server 127.0.0.1:5105;      # Bokeh Server 5
}

We have labeled this upstream stanza as myapp. We will use this name below. Additionally, we have listed the internal connection information for six different Bokeh server instances (each running on a different port) inside the stanza. You can run and list as many Bokeh servers as you need.

You would run the Bokeh servers with commands similar to:

serve myapp.py --port 5100
serve myapp.py --port 5101
...

Next, in the location stanza for our Bokeh server, change the proxy_pass value to refer to the upstream stanza we created above. In this case we use proxy_pass http://myapp; as shown here:

server {

    location / {
        proxy_pass http://myapp;

        # all other settings unchanged
        proxy_set_header Upgrade $http_upgrade;
        proxy_set_header Connection "upgrade";
        proxy_http_version 1.1;
        proxy_set_header X-Forwarded-For $proxy_add_x_forwarded_for;
        proxy_set_header Host $host:$server_port;
        proxy_buffering off;
    }

}

Authentication

The Bokeh server itself does not have any facilities for authentication or authorization. However, the Bokeh server can be configured with an “Auth Provider” that hooks in to Tornado’s underlying capabilities. For background information, see the Tornado docs for Authentication and security. The rest of this section assumes some familiarity with that material.

Auth Module

The Bokeh server can be configured to only allow connections in case there is a properly authenticated user. This is accomplished by providing the path to a module that implements the necessary functions on the command line:

bokeh serve --auth-module=/path/to/auth.py

or by setting the BOKEH_AUTH_MODULE environment variable.

The module must contain one of the following two functions that will return the current user (or None):

def get_user(request_handler):
    pass

async def get_user_async(request_handler):
    pass

The function is passed the Tornado RequestHandler and can inspect cookies or request headers to determine the authenticated user. If there is no valid authenticated user, these functions should return None.

Additionally, the module must specify where to redirect unauthenticated users. It must contain either:

  • a module attribute login_url and (optionally) a LoginHandler class

  • a function definition for get_login_url

login_url = "..."

class LoginHandler(RequestHandler):
    pass

def get_login_url(request_handler):
    pass

When a relative login_url is given, an optional LoginHandler class may also be provided, and it will be installed as a route on the Bokeh server automatically.

The get_login_url function is useful in cases where the login URL must vary based on the request, or cookies, etc. It is not possible to specify a LoginHandler when get_url_function is defined.

Analogous to the login options, optional logout_url and LogoutHandler values may be define an endpoint for logging users out.

If no auth module is provided, then a default user will be assumed, and no authentication will be required to access Bokeh server endpoints.

Warning

The contents of the auth module will be executed!

Secure Cookies

If you want to use Tornado’s set_secure_cookie and get_secure_cookie functions in your auth module, a cookie secret must be set. This can be accomplished with the BOKEH_COOKIE_SECRET environment variable. e.g.

export BOKEH_COOKIE_SECRET=<cookie secret value>

The value should be a long, random sequence of bytes

Security

By default, a Bokeh server will accept any incoming connections on allowed websocket origins. If a session ID is specified, and a session with that ID already exists on the server, then a connection to that session is made. Otherwise, a new session is automatically created and used.

If you are deploying an embedded Bokeh app within a large organization or to the wider internet, you may want to limit who can initiate sessions, and from where. Bokeh has options to restrict session creation.

Websocket Origin

When an HTTP request is made to the Bokeh server, it immediately returns a script that will initiate a websocket connection, and all subsequent communication happens over the websocket. To reduce the risk of cross-site misuse, the bokeh server will only initiate websocket connections from origins that are explicitly allowlisted. Requests with Origin headers that do not match the allowlist will generate HTTP 403 error responses.

By default only localhost:5006 is allowlisted. I.e the following two invocations are identical:

bokeh serve --show myapp.py

and

bokeh serve --show --allow-websocket-origin=localhost:5006 myapp.py

Both of these will open a browser to the default application URL localhost:5006 and since localhost:5006 is in the allowed websocket origin allowlist, the Bokeh server will create and display a new session.

Now, consider when a Bokeh server is embedded inside another web page, using server_document() or server_session(). In this instance, the “Origin” header for the request to the Bokeh server is the URL of page that has the Bokeh content embedded it. For example, if a user navigates to our page at https://acme.com/products, which has a Bokeh application embedded in it, then the origin header reported by the browser will be acme.com. In this instance, we typically want to restrict the Bokeh server to honoring only requests that originate from our acme.com page, so that other pages cannot embed our Bokeh app without our knowledge.

This can be accomplished by setting the --allow-websocket-origin command line argument:

bokeh serve --show --allow-websocket-origin=acme:com myapp.py

This will prevent other sites from embedding our Bokeh application in their pages, because requests from users viewing those pages will report a different origin than acme.com, and the Bokeh server will reject them.

Warning

Bear in mind that this only prevents other web pages from surreptitiously embedding our Bokeh app to an audience using standard web browsers. A determined and knowledgeable attacker can spoof Origin headers.

If multiple allowed origins are required, then multiple instances of --allow-websocket-origin can be passed on the command line.

It is also possible to configure a Bokeh server to allow any and all connections Regardless of origin:

bokeh serve --show --allow-websocket-origin='*' myapp.py

This is not recommended outside testing and experimentation.

Signed session IDs

By default, the Bokeh server will automatically create new sessions for all new requests from allowed websocket origins, even if no session ID is provided. When embedding a Bokeh app inside another web application (e.g. Flask, Django), we would like ensure that our web application, and only our web application, is capable of generating proper requests to the Bokeh server. It is possible to configure the Bokeh server to only create sessions when a cryptographically signed session ID is provided.

To do this, you need to first create a secret for signing session ids with, using the bokeh secret command, e.g.

export BOKEH_SECRET_KEY=`bokeh secret`

Then set BOKEH_SIGN_SESSIONS when starting the Bokeh server (and typically also set the allowed websocket origin):

BOKEH_SIGN_SESSIONS=yes bokeh serve --allow-websocket-origin=acme.com myapp.py

Then in your web application, we explicitly provide (signed) session ids using generate_session_id:

from bokeh.util.token import generate_session_id

script = server_session(url='http://localhost:5006/bkapp',
                        session_id=generate_session_id())
return render_template("embed.html", script=script, template="Flask")

Make sure that the BOKEH_SECRET_KEY environment variable is set (and identical) for both the Bokeh server and web app processes (e.g. Flask or Django or whatever tool is in use).

Note

Signed session IDs are effectively access tokens. As with any token system, security is predicated on keeping the token a secret. It is also advised to run the Bokeh server behind a proxy that terminates SSL, so that the session ID is transmitted securely to the user’s browser.

XSRF Cookies

Bokeh can enable the use of Tornado’s cross-site request forgery protection protection. To turn this feature on, use the --enable-xsrf-cookies option, or set the environment variable BOKEH_XSRF_COOKIES=yes. If this setting is enabled, any PUT, POST, or DELETE operations on custom or login handlers must be instrumented properly in order to function. Typically, this means adding the code:

{% module xsrf_form_html() %}

to all HTML form submission templates. For full details, see the Tornado documentation on XSRF Cookies.

Scaling the server

You can fork multiple server processes with the num-procs option. For example, to fork 3 processes:

bokeh serve --num-procs 3

Note that the forking operation happens in the underlying Tornado Server, see notes in the Tornado docs.

Further Reading

Now that you are familiar with the concepts of Running a Bokeh Server, you may be interested in learning more about the internals of the Bokeh server in Server Architecture